Information sending method and device and information receiving method and device

ABSTRACT

Information transmission and reception methods and apparatus are disclosed, where the transmission method includes: carrying configuration information of a control resource set on a physical broadcast channel; where the configuration information is used to indicate to a terminal at least one of the following of the control resource set: time domain position information and frequency domain position information; and transmitting the control resource set to the terminal according to the configuration information.

CROSS REFERENCE TO RELATED APPLICATIONS

The present application is a continuation of U.S. Ser. No. 16/875,701,filed May 15, 2020 which is a continuation of PCT/CN2018/116114, filedNov. 19, 2018 which claims the priority of Chinese Patent ApplicationNo. 201711148126.3, filed in the Chinese Patent Office on Nov. 17, 2017,the entire contents of which are herein incorporated by reference.

TECHNICAL FIELD

The present application relates to the field of communications, forexample, information transmission and reception methods and apparatuses.

BACKGROUD

In a new generation of a radio communication system (New Radio, NR),system information is divided into minimum system information (minimumSI) and other system information (other SI). The minimum systeminformation is divided into “master system information (MaterInformation Block, MIB)” carried on a physical broadcast channel(Physical Broadcast Channel, PBCH), and “remaining minimum systeminformation (remaining minimum SI, RMSI)” carried on a physical downlinkshared channel; and the master system information is used to providebasic system parameters of a cell, and the remaining minimum systeminformation is used to provide configuration information related toinitial access, such as transmission configuration of an initial accessrequest, and message reception configuration of an initial accessresponse. Other system information that needs to be broadcast isreferred to as other system information.

The RMSI is scheduled by a physical downlink control channel (PhysicalDownlink Control Channel, PDCCH), and carried on the physical downlinkshared channel (Physical Downlink Shared Channel, PDSCH). Time andfrequency domain positions of a common control-resource set(control-resource set, CORESET) where RMSI scheduling information islocated may be indicated in the PBCH.

In the NR system, the PBCH is carried in a synchronization signal(Synchronization Signal, SS)/physical broadcast channel block (PBCHblock) and transmitted, one synchronization period includes a pluralityof SS/PBCH blocks, and different SS/PBCH blocks may transmit synchronousbroadcast signals of the same or different beam directions or portstogether to implement full coverage of an expected region. PBCHs ofdifferent beam directions and ports have a need for combined reception;therefore, it is necessary to ensure that information contents are thesame in considering an introduction of indication information into thePBCHs.

To ensure flexibility of data transmission, relationships between timedomain positions of different SS/PBCH blocks and time domain positionsof respectively corresponding RMSI common control resource sets may bedifferent, and there is no effective solution in the related art for howto effectively indicate a time domain position of an RMSI common controlresource set without affecting combined reception of PBCHs.

SUMMARY

Embodiments of the present application provide information transmissionand reception methods and apparatuses to at least solve a technicalproblem in the related art that time and frequency domain resourcepositions of a control resource set cannot be effectively indicatedwithout affecting combined reception of PBCHs.

According to an embodiment of the present application, provided is aninformation transmission method, including: carrying configurationinformation of a control resource set on a physical broadcast channel;where the configuration information is used to indicate to a terminal atleast one of the following of the control resource set: time domainposition information and frequency domain position information; andtransmitting the control resource set to the terminal according to theconfiguration information.

According to an embodiment of the present application, provided isanother information reception method, including: receiving configurationinformation of a control resource set, where the configurationinformation of the control resource set is carried on a physicalbroadcast channel, and the configuration information is used to indicateat least one of the following of the control resource set: time domainposition information and frequency domain position information; andreceiving the control resource set according to the configurationinformation.

According to another embodiment of the present application, provided isan information transmission apparatus, including: a configuration moduleconfigured to carry configuration information of a control resource seton a physical broadcast channel; where the configuration information isused to indicate to a terminal at least one of the following of thecontrol resource set: time domain position information and frequencydomain position information; and a transmitting module configured totransmit the control resource set according to the configurationinformation.

According another embodiment of the present application, provided isanother information reception apparatus, including: a first receivingmodule configured to receive configuration information of a controlresource set, where the configuration information of the controlresource set is carried on a physical broadcast channel, and theconfiguration information is used to indicate at least one of thefollowing of the control resource set: time domain position informationand frequency domain position information; and a second receiving moduleconfigured to receive the control resource set according to theconfiguration information.

According to a further embodiment of the present application, furtherprovided is a storage medium, including a stored program, where themethod according to any one of the foregoing is executed when theprogram is run.

According to a further embodiment of the present application, furtherprovided is a processor, configured to run a program, where the methodaccording to any one of the foregoing is executed when the program isrun.

BRIEF DESCRIPTION OF DRAWINGS

The drawings described herein are used to provide a furtherunderstanding of the present application and form a part of the presentapplication; and the illustrative embodiments of the present applicationand the description thereof are used to explain the present applicationand are not intended to limit the present application. In the drawings:

FIG. 1 is a flowchart of an information transmission method according toan embodiment of the present application;

FIG. 2 is a flowchart of an information reception method according to anembodiment of the present application;

FIG. 3 is a structural block diagram of an information transmissionapparatus according to an embodiment of the present application;

FIG. 4 is a structural block diagram of an information receptionapparatus according to an embodiment of the present application;

FIG. 5 is a schematic diagram of a synchronization signal blockaccording to the present embodiment;

FIG. 6 is a schematic diagram I that a frequency domain position isindicated by a frequency offset between a control resource set and asynchronization signal block according to the present embodiment;

FIG. 7 is a schematic diagram II that a frequency domain position isindicated by a frequency offset between a control resource set and asynchronization signal block according to the present embodiment;

FIG. 8 is a schematic diagram III that a frequency domain position isindicated by a frequency offset between a control resource set and asynchronization signal block according to the present embodiment;

FIG. 9 is a schematic diagram IV that a frequency domain position isindicated by a frequency offset between a control resource set and asynchronization signal block according to the present embodiment;

FIG. 10 is a schematic diagram V that a frequency domain position isindicated by a frequency offset between a control resource set and asynchronization signal block according to the present embodiment;

FIG. 11 is a schematic diagram VI that a frequency domain position isindicated by a frequency offset between a control resource set and asynchronization signal block according to the present embodiment;

FIG. 12 is a schematic structural diagram that a CORESET is transmittedonly in a slot in which an SSB is located according to the presentembodiment;

FIG. 13 is a schematic diagram of use of a plurality of synchronizationsignal block transmission periods according to the present embodiment;

FIG. 14 is a schematic diagram of mapping patterns of a currentsynchronization signal block (SSB) to a slot according the presentembodiment;

FIG. 15 is a schematic diagram I of position information of a symboloccupied by a CORESET in a slot according to the present embodiment;

FIG. 16 is a schematic diagram II of position information of a symboloccupied by a CORESET in a slot according to the present embodiment;

FIG. 17 is a schematic diagram I that a CORESET is mapped to a slotoutside an SSB according to the present embodiment;

FIG. 18 is a schematic diagram II that a CORESET is mapped to a slotoutside an SSB according to the present embodiment;

FIG. 19 is a schematic diagram that a CORESET is transmitted in a slotcontaining a synchronization signal block according the presentembodiment;

FIG. 20 is a schematic diagram that a CORESET is transmitted in a slotnot containing a synchronization signal block according the presentembodiment;

FIG. 21 is a schematic diagram that a CORESET is transmitted in a slotcontaining a synchronization signal block and transmitted in a slot notcontaining the synchronization signal block according the presentembodiment;

FIG. 22 is a schematic diagram that a CORESET is transmitted in a slotin which a synchronization signal block is located according the presentembodiment;

FIG. 23 is a schematic diagram I that a CORESET is transmitted in a slotnot containing a synchronization signal block according the presentembodiment;

FIG. 24 is a schematic diagram II that a CORESET is transmitted in aslot not containing a synchronization signal block according the presentembodiment;

FIG. 25 is a schematic diagram that all synchronization signal blockscorrespond to a same CORESET monitoring window according the presentembodiment; and

FIG. 26 is a schematic diagram that a plurality of synchronizationsignal blocks corresponds to one CORESET monitoring window according thepresent embodiment.

DESCRIPTION OF EMBODIMENTS

The present application will be illustrated in detail below withreference to the drawings in conjunction with embodiments. It should benoted that, the embodiments of the present application and features inthe embodiments may be mutually combined provided that no conflict iscaused.

It should be noted that, the terms “first”, “second”, and the like inthe specification, claims, and accompanying drawings of the presentapplication are intended to distinguish between similar objects but donot necessarily indicate a specific order or sequence.

Embodiment 1

In the embodiment of the present application, a network architecturethat can be run includes: a base station and a terminal, where aninformation exchange is performed between the base station and theterminal.

An information transmission method applied to the foregoing networkarchitecture is provided in the present embodiment. FIG. 1 is aflowchart of an information transmission method according to anembodiment of the present application, and as shown in FIG. 1 , the flowincludes: a step S102 and a step S104. In the step S102, configurationinformation of a control resource set is carried on a physical broadcastchannel.

The configuration information is used to indicate to a terminal at leastone of the following of the control resource set: time domain positioninformation and frequency domain position information.

In the step S104, the control resource set is transmitted to theterminal according to the configuration information.

Through the foregoing steps, by carrying configuration information of acontrol resource set on a physical broadcast channel and transmittingthe control resource set to a terminal according to the configurationinformation, a technical problem in the related art that time andfrequency domain resource positions of a control resource set cannot beeffectively indicated without affecting combined reception of PBCHs issolved, and flexibility of data transmission is improved.

In an embodiment, an execution body of the foregoing steps may be at anetwork side, such as a base station, but it is not limited hereto.

In an embodiment, the configuration information of the control resourceset includes: bandwidth information of the control resource set.

In an embodiment, the bandwidth information includes at least one of thefollowing: a minimum channel bandwidth and a minimum terminal bandwidth.

In an embodiment, the configuration information of the control resourceset includes the frequency domain position information of the controlresource set, where the frequency domain position information isindicated by a frequency offset between the control resource set and asynchronization signal block.

In an embodiment, the frequency domain position information of thecontrol resource set is indicated by one of the following:

-   -   an offset between a center frequency of the control resource set        and a center frequency of the synchronization signal block being        M×SC_(SSB);    -   an offset between a center frequency of the control resource set        and a center frequency of the synchronization signal block being        (BW_(CORESET)−BW_(SSB))/2−M×SC_(SSB);    -   an offset between a center frequency of the control resource set        and a center frequency of the synchronization signal block being        (BW_(CORESET)−BW_(SSB))/2−(12×SC_(CORESET)−M×SC_(SSB));    -   an offset between a center frequency of the control resource set        and a center frequency of the synchronization signal block being        (BW_(CORESET)BW_(SSB))/2+M×SC_(SSB); and    -   an offset between a center frequency of the control resource set        and a center frequency of the synchronization signal block being        (BW_(CORESET)+BW_(SSB))/2+(12×SC_(CORESET)+M×SC_(SSB));    -   where M is a number of synchronization signal block subcarriers        in a frequency domain offset between the synchronization signal        block and a carrier physical resource block grid (PRB grid), M        is an integer, SC_(CORESET) is a frequency domain width of a        control resource set subcarrier, SC_(SSB) is a frequency domain        width of a synchronization signal block subcarrier, BW_(CORESET)        is a control resource set bandwidth, and BW_(SSB) is a        synchronization signal block bandwidth.

In an embodiment, the configuration information of the control resourceset includes the time domain position information of the controlresource set; where the time domain position information includes atleast one of the following information: information of a slot in whichthe control resource set is located and position information of a symboloccupied by the control resource set in the slot.

In an embodiment, the position information of the symbol occupied by thecontrol resource set in the slot includes: a starting symbol index ofthe symbol occupied by the control resource set in the slot and a numberof symbols occupied by the control resource set in the slot.

In an embodiment, the information of the slot in which the controlresource set is located includes one of the following:

-   -   the control resource set is transmitted in a slot containing a        synchronization signal block;    -   the control resource set is transmitted in a slot not containing        a synchronization signal block; and    -   the control resource set is transmitted in a slot containing a        synchronization signal block and transmitted in a slot not        containing the synchronization signal block.

In an embodiment, the configuration information of the control resourceset is further used to indicate: whether the control resource set istransmitted in the slot containing a synchronization signal block; orwhether the control resource set is transmitted in the slot notcontaining a synchronization signal block.

In an embodiment, when the control resource set is transmitted in theslot containing a synchronization signal block and transmitted in theslot not containing the synchronization signal block, a same resourcemapping rule is adopted for the control resource set in the slotcontaining a synchronization signal block and in the slot not containingthe synchronization signal block.

In an embodiment, the configuration information of the control resourceset includes monitoring window configuration information of the controlresource set, where the monitoring window configuration information ofthe control resource set includes at least one of the followinginformation: a monitoring period of the control resource set, timedomain duration of a monitoring window, a time domain offset betweenadjacent monitoring windows, and a starting position of the monitoringwindow, where a monitoring window of the control resource set includesat least one monitoring occasion of the control resource set.

In an embodiment, the monitoring window of the control resource setcorresponds to a synchronization signal block.

In an embodiment, the time domain duration of the monitoring window ofthe control resource set is greater than or equal to 1 slot.

In an embodiment, the time domain offset between the adjacent monitoringwindows includes at least one of the following: 0, the time domainduration of the monitoring window, and 1/X of the time domain durationof the monitoring window, where X is an integer greater than 1, and avalue of X is predefined by a predetermined protocol or indicated by asignaling.

In an embodiment, when the time domain duration of the monitoring windowof the control resource set is 1 slot, the time domain offset betweenthe adjacent monitoring windows is the time domain duration of themonitoring window, or 1/X of the time domain duration of the monitoringwindow; and when the time domain duration of the monitoring window ofthe control resource set is greater than 1 slot, the time domain offsetbetween the adjacent monitoring windows is 0, or 1/X of the time domainduration of the monitoring window.

In an embodiment, the starting position of the monitoring window isindicated by a time domain offset between the starting position of themonitoring window and a starting slot of a synchronization signal block,or the starting position of the monitoring window is fixedly configured.

In an embodiment, the control resource set is one of the following: acommon control resource set of remaining minimum system information RMSIand a common control resource set of paging information.

An information reception method applied to the foregoing networkarchitecture is provided in the present embodiment. FIG. 2 is aflowchart of an information reception method according to an embodimentof the present application, and as shown in FIG. 2 , the flow includesthe following steps: a step S202 and a step S204.

In the step S202, configuration information of a control resource set isreceived.

The configuration information of the control resource set is carried ona physical broadcast channel, and the configuration information is usedto indicate at least one of the following of the control resource set:time domain position information and frequency domain positioninformation.

In the step S204, the control resource set is received according to theconfiguration information.

In an embodiment, the configuration information of the control resourceset includes: bandwidth information of the control resource set.

In an embodiment, the configuration information of the control resourceset includes: the frequency domain position information of the controlresource set, where the frequency domain position information isindicated by a frequency offset between the control resource set and asynchronization signal block.

In an embodiment, the frequency domain position information of thecontrol resource set is indicated by one of the following:

-   -   an offset between a center frequency of the control resource set        and a center frequency of the synchronization signal block being        M×SC_(SSB);    -   an offset between a center frequency of the control resource set        and a center frequency of the synchronization signal block being        (BW_(CORESET)−BW_(SSB))/2−M×SC_(SSB);    -   an offset between a center frequency of the control resource set        and a center frequency of the synchronization signal block being        (BW_(CORESET)−BW_(SSB))/2−(12×SC_(CORESET)−M×SC_(SSB));    -   an offset between a center frequency of the control resource set        and a center frequency of the synchronization signal block being        (BW_(CORESET)+BW_(SSB))/2+M×SC_(SSB); and    -   an offset between a center frequency of the control resource set        and a center frequency of the synchronization signal block being        (BW_(CORESET)+BW_(SSB))/2+(12×SC_(CORESET)+M×SC_(SSB));    -   where M is a number of synchronization signal block subcarriers        in a frequency domain offset between the synchronization signal        block and a carrier physical resource block grid (PRB grid), M        is an integer, SC_(CORESET) is a frequency domain width of a        control resource set subcarrier, SC_(SSB) is a frequency domain        width of a synchronization signal block subcarrier, BW_(CORESET)        is the control resource set bandwidth, and BW_(SSB) is the        synchronization signal block bandwidth.

In an embodiment, the configuration information of the control resourceset includes the time domain position information of the controlresource set; where the time domain position information includes atleast one of the following information: information of a slot in whichthe control resource set is located and position information of a symboloccupied by the control resource set in the slot.

In an embodiment, the configuration information of the control resourceset includes monitoring window configuration information of the controlresource set, where the monitoring window configuration information ofthe control resource set includes at least one of the followinginformation: a monitoring period of the control resource set, timedomain duration of a monitoring window, a time domain offset betweenadjacent monitoring windows, and a starting position of the monitoringwindow, where a monitoring window of the control resource set includesat least one monitoring occasion of the control resource set.

From the description of the foregoing implementation manners, thoseskilled in the art would clearly understand that the present applicationcan be implemented by software together with the necessarygeneral-purpose hardware according to the methods of the foregoingembodiments, and certainly can also be achieved only by hardware, butthe former would be preferred. Based on such understanding, thetechnical solutions of the present application substantially, or thepart of the present application making contribution to the prior art maybe embodied in the form of a software product, and the computer softwareproduct is stored in a storage medium (such as a ROM/RAM, a magneticdisk, or an optical disk), which includes multiple instructions enablingterminal equipment (which may be a cell phone, a computer, a server,network equipment or the like) to execute the methods described in theembodiments of the present application.

Embodiment 2

In the present embodiment, further provided are information transmissionand reception apparatuses, and the apparatuses are configured toimplement the foregoing embodiment and preferred implementation manners,and what has been illustrated will not be repeated redundantly. As usedhereinafter, the term “module” may implement at least one of softwareand hardware for a predetermined function. Although the apparatusesdescribed in the following embodiment is preferably implemented bysoftware, the implementation of hardware or a combination of softwareand hardware is also possible and conceivable.

FIG. 3 is a structural block diagram of an information transmissionapparatus according to an embodiment of the present application, and itmay be applied to a network element at a network side, such as a basestation; and as shown in FIG. 3 , the apparatus includes: aconfiguration module 30 and a transmitting module 32.

The configuration module 30 is configured to carry configurationinformation of a control resource set on a physical broadcast channel;where the configuration information is used to indicate to a terminal atleast one of the following of the control resource set: time domainposition information and frequency domain position information.

The transmitting module 32 is configured to transmit the controlresource set according to the configuration information.

FIG. 4 is a structural block diagram of an information receptionapparatus according to an embodiment of the present application, and itmay be applied to a terminal; and as shown in FIG. 4 , the apparatusincludes: a first receiving module 40 and a second receiving module 42.

The first receiving module 40 is configured to receive configurationinformation of a control resource set, where the configurationinformation of the control resource set is carried on a physicalbroadcast channel, and the configuration information is used to indicateat least one of the following of the control resource set: time domainposition information and frequency domain position information.

The second receiving module 42 is configured to receive the controlresource set according to the configuration information.

It should be noted that, each of the foregoing modules may beimplemented by software or hardware; and for the latter, it may beimplemented by the following manner, but is not limited hereto: theforegoing modules are located in a same processor; or each of theforegoing modules is respectively located in different processors in anycombination.

Embodiment 3

To ensure flexibility of data transmission, relationships between timedomain positions of different SS/PBCH blocks and time domain positionsof respectively corresponding RMSI common control resource sets may bedifferent, and how to effectively indicate a time domain position of anRMSI common control resource set without affecting combined reception ofPBCHs is a problem that must be considered and solved.

In a new generation of a radio communication system NR, systeminformation is divided into minimum system information (minimum SI) andother system information (other SI). The minimum system information isfurther divided into “master system information (MIB)” carried on aphysical broadcast channel (PBCH), and “remaining minimum systeminformation” carried on a physical downlink shared channel; and themaster system information is used to provide basic system parameters ofa cell, and the remaining minimum system information is used to provideconfiguration information related to initial access, such astransmission configuration of an initial access request, and messagereception configuration of an initial access response. Other systeminformation that needs to be broadcast is referred to as other systeminformation.

The RMSI is scheduled by a physical downlink control channel PDCCH, andcarried on the physical downlink shared channel PDSCH. Time andfrequency domain positions of a common control resource set CORESETwhere RMSI scheduling information is located may be indicated in thePBCH.

In the NR system, the PBCH is carried in a synchronizationsignal/physical broadcast channel block (SS/PBCH block) and transmitted,one synchronization period includes a plurality of SS/PBCH blocks, anddifferent SS/PBCH blocks may transmit synchronous broadcast signals ofthe same or different beam directions or ports together to implementfull coverage of an expected region. PBCHs of different beam directionsand ports have a need for combined reception; therefore, it is necessaryto ensure that information contents are the same in considering anintroduction of indication information into the PBCHs.

To ensure flexibility of data transmission, relationships between timedomain positions of different SS/PBCH blocks and time domain positionsof respectively corresponding RMSI common control resource sets may bedifferent, and how to effectively indicate a time domain position of anRMSI common control resource set without affecting combined reception ofPBCHs is a problem that must be considered and solved.

The present application provides an information transmission method andsystem, including the following manners:

-   -   carrying, at a network side, configuration information of a        control resource set (Control Resource Set, CORESET) on a        physical broadcast channel; where the configuration information        of the control resource set is used to indicate time and        frequency domain position information of the control resource        set to a terminal; and    -   transmitting, at the network side, the control resource set        CORESET according to the configuration information.

The configuration information of the control resource set includes oneor more of the following:

-   -   bandwidth information of the control resource set;    -   the frequency domain position information of the control        resource set;    -   the time domain position information of the control resource        set; where the time domain position information includes at        least one of the following information: information of a slot in        which the control resource set is located and position        information of a symbol occupied by the control resource set in        the slot. The position information of the symbol occupied by the        control resource set in the slot includes: a starting symbol        index of the symbol occupied by the control resource set in the        slot and a number of symbols occupied by the control resource        set in the slot; and    -   monitoring window configuration information of the control        resource set; where the monitoring window configuration        information of the control resource set includes at least one of        the following information: a monitoring period of the control        resource set, time domain duration of a monitoring window, a        time domain offset between adjacent monitoring windows, and a        starting position of the monitoring window.

A common control resource set CORESET of the present embodiment mayinclude one or more of the following downlink control information:paging downlink control information, scheduling information of remainingminimum system information, a paging indicator, and the like. Since theinformation needs to implement full coverage of an expected range,common control information of a certain specific downlink port/downlinkbeam direction is transmitted in a certain CORESET; and one or moreCORESETs are included in one sweeping transmission period/CORESETmonitoring period, and the transmission of common control information ofone or more downlink ports/downlink beam directions implements thecoverage of the expected range.

The paging downlink control information (paging DCI) is used to indicatescheduling information of a paging message, and also referred to aspaging scheduling downlink control information (paging scheduling DCI).

In a new generation of a radio communication system NR, systeminformation is divided into minimum system information (minimum SI) andother system information (other SI). The minimum system information isfurther divided into “master system information (MIB)” carried on aphysical broadcast channel (PBCH), and “remaining minimum systeminformation” carried on a physical downlink shared channel; and themaster system information is used to provide basic system parameters ofa cell, and the remaining minimum system information is used to provideconfiguration information related to initial access, such astransmission configuration of an initial access request, and messagereception configuration of an initial access response. Other systeminformation that needs to be broadcast is referred to as other systeminformation (other SI).

The RMSI is scheduled by a physical downlink control channel PDCCH, andcarried on the physical downlink shared channel PDSCH. Time andfrequency domain positions of a common control resource set CORESETwhere RMSI scheduling information is located may be indicated in thePBCH.

The paging indicator is used to trigger a terminal to report a downlinkpreferred beam, and is also referred to as paging group indicator.

A synchronization signal block (SS/PBCH block) is times and frequenciesdomain resources used to carry accessing related signal channels, suchas a synchronization signal and a physical broadcast channel (and acorresponding demodulation reference signal DMRS). FIG. 5 is a schematicdiagram of a synchronization signal block according the presentembodiment; and as shown in FIG. 5 , the synchronization signal blockusually includes 4 symbols, the first and third symbols carry a primarysynchronization signal (PSS) and a secondary synchronization signal(SSS), respectively, and synchronization signal sequences are mapped to127 resource elements (RE) in 12 physical resource blocks (PRB). Asshown in (a) of FIG. 5 , in some configurations, physical broadcastchannels (PBCHs) are only carried on the second and fourth symbols inthe synchronization signal block, and occupy 24 PRBs; or in otherresource configurations, PBCHs are mapped to the second, third andfourth symbols in the synchronization signal block, and on the pluralityof symbols, the numbers of occupied PRBs are as follows: 20 PRBs areoccupied on the second and fourth symbols, and on the third symbol, aPBCH occupies 4 PRBs respectively on two sides of the secondarysynchronization signal, a total of 8 PRBs. In the foregoingconfigurations, center frequencies of the synchronization signals arealigned with center frequencies of the PBCHs.

The present embodiment further includes the following implementationmanners.

Implementation Manner 1:

The present implementation manner describes an indication of bandwidthinformation of the CORESET, which is particularly described as follows:the configuration information of the control resource set includes thatthe bandwidth information of the control resource set may be the minimumchannel bandwidth or the minimum terminal bandwidth.

The minimum channel bandwidth is defined as a minimum bandwidthsupported by a system within a certain frequency range; for example,within a frequency range below 6 GHz, the minimum channel bandwidth isdefined as 5 MHz; or within a frequency range above 6 GHz, the minimumchannel bandwidth is defined as 50 MHz.

The minimum terminal bandwidth refers to a maximum value of bandwidththat are capable of being supported by all terminals.

For the indication of the CORESET bandwidth information, 1 bit (bit) maybe included in a physical broadcast channel to indicate whether theCORESET bandwidth of a current carrier is the minimum channel bandwidthor the minimum terminal bandwidth. For example, 0 represents that theCORESET bandwidth of the current carrier is the minimum channelbandwidth, and 1 represents that the CORESET bandwidth of the currentcarrier is the minimum terminal bandwidth.

Alternatively, the CORESET bandwidth is predefined based on a frequencyband; for example, it is specified in a protocol that the CORESETbandwidth of a certain frequency band is equal to the minimum channelbandwidth or the minimum terminal bandwidth. Alternatively, a value ofthe CORESET bandwidth of a frequency band is given in a protocol, suchas 24 PRBs (physical transmission block), or 48 PRBs. In this case, itis unnecessary to introduce a bandwidth indication bit separately.

Alternatively, the CORESET bandwidth is implicitly indicated by a numberof symbols occupied by the control resource set in a slot; for example,the number of symbols occupied by the CORESET in a slot is 1, whichcorresponds to that the CORESET bandwidth is 48 PRBs; and when thenumber of symbols occupied by the CORESET in the slot is 2, and theCORESET bandwidth is 24 PRBs. In this case, it is unnecessary tointroduce a bandwidth indication bit separately.

Implementation Manner 2:

The present implementation manner describes an indication of CORESETfrequency domain position information, which is described as follows:the configuration information of the control resource set includes thefrequency domain position information of the control resource set; wherethe frequency domain position is indicated by a frequency offset betweenthe control resource set and a synchronization signal block.

FIG. 6 is a schematic diagram I that a frequency domain position isindicated by a frequency offset between the control resource set and asynchronization signal block according to the present embodiment, FIG. 7is a schematic diagram II that a frequency domain position is indicatedby a frequency offset between the control resource set and asynchronization signal block according to the present embodiment, FIG. 8is a schematic diagram III that a frequency domain position is indicatedby a frequency offset between the control resource set and asynchronization signal block according to the present embodiment, FIG. 9is a schematic diagram IV that a frequency domain position is indicatedby a frequency offset between the control resource set and asynchronization signal block according to the present embodiment, FIG.10 is a schematic diagram V that a frequency domain position isindicated by a frequency offset between the control resource set and asynchronization signal block according to the present embodiment, andFIG. 11 is a schematic diagram VI that a frequency domain position isindicated by a frequency offset between the control resource set and asynchronization signal block according to the present embodiment. Asshown in FIGS. 6, 7, 8, 9, 10 and 11 , there may be offsets (asillustration of offsets) between physical resource block PRB boundariesof a synchronization signal block and actual PRB boundaries of a carrier(physical resource block grid (PRB grid)). An Information bit (such as 4bits or 5 bits) may be introduced into a physical broadcast channel toexplicitly indicate the foregoing offset, and the offset may bepredefined as an offset between a physical resource block PRB boundaryof a synchronization signal block and a PRB boundary of a carrier at alower frequency (as shown in FIGS. 6, 8 and 10 ), or an offset between aphysical resource block PRB boundary of a synchronization signal blockand a PRB boundary of a carrier at a higher frequency (as shown in FIGS.7, 9 and 11 ); however, there is no offset between transmission of aCORESET and an actual PRB boundary of a carrier; therefore, when thefrequency domain position of the CORESET is indicated by using afrequency offset from a synchronization signal block, it is necessary totake this offset into account; and indication manners for the CORESETfrequency domain position are described below respectively whensubcarrier spacing of the CORESET is equal to, less than or greater thansubcarrier spacing of the synchronization signal block.

When the subcarrier spacing of the CORESET is equal to the subcarrierspacing of the synchronization signal block (for example, the subcarrierspacing of the CORESET and the synchronization signal block is 15 kHz),as shown in FIGS. 6 and 7 , in a carrier physical resource block grid(PRB grid), one carrier PRB includes 12 synchronization signal blocksubcarriers in frequency domain; therefore, there are 12 possible offsetvalues, that is, a range of a value of the offset is 0 to 11subcarriers, and a particular offset number (that is, the value of theoffset) is indicated by 4 bits in the PBCH.

As shown in FIGS. 8 and 9 , when the subcarrier spacing of the CORESETis less than the subcarrier spacing of the synchronization signal block(for example, the subcarrier spacing of the CORESET is 15 kHz, and thesubcarrier spacing of the synchronization signal block is 30 kHz), acarrier physical resource block grid (PRB grid) is defined by thegreater subcarrier spacing (30 kHz), and a smaller subcarrier is nestedwithin a greater subcarrier, that is, one 30 kHz subcarrier correspondsto two 15 kHz subcarriers in frequency domain. In this case, in thecarrier physical resource block grid (PRB grid), one carrier PRBincludes 12 synchronization signal block subcarriers in frequencydomain, a range of a value of the offset (offset) is 0 to 11synchronization signal block (30 kHz) subcarriers, and a particularoffset number (that is, the value of the offset) is indicated by 4 bitsin the PBCH.

As shown in FIGS. 10 and 11 , when the subcarrier spacing of the CORESETis greater than the subcarrier spacing of the synchronization signalblock (for example, the subcarrier spacing of the CORESET is 30 kHz, andthe subcarrier spacing of the synchronization signal block is 15 kHz), acarrier physical resource block grid (PRB grid) is defined by thegreater subcarrier spacing (30 kHz), and a smaller subcarrier is nestedwithin a greater subcarrier, that is, 1 30 kHz subcarrier corresponds to2 15 kHz subcarriers in frequency domain. In this case, in the carrierphysical resource block grid (PRB grid), one carrier PRB includes 24synchronization signal block subcarriers in frequency domain, a range ofa value of the offset (offset) is 0 to 23 synchronization signal block(30 kHz) subcarriers, and a particular offset number (that is, the valueof the offset) is indicated by 5 bits in the PBCH.

Sub-Implementation Manner 2.1:

When the offset is defined as an offset between a physical resourceblock PRB boundary of the synchronization signal block and a PRBboundary of a carrier at a lower frequency (as shown in FIGS. 6, 8 and10 ), the frequency domain position of the CORESET is one of case 1 tocase 5 of the following frequency domain position.

Case 1: a low frequency boundary of the CORESET is lower than a lowfrequency boundary of the synchronization signal block by M 15 kHzsubcarriers; and in this case, an offset between a center frequency ofthe CORESET and a center frequency of the synchronization signal blockis (BW_(CORESET)−BW_(SSB))/2−M×SC_(SSB).

Case 2: a high frequency boundary of the CORESET is higher than a highfrequency boundary of the synchronization signal block by12×SC_(CORESET)−M×SC_(SSB); and in this case, an offset between a centerfrequency of the CORESET and a center frequency of the synchronizationsignal block is (BW_(CORESET)−BW_(SSB))/2−(12×SC_(CORESET)−M×SC_(SSB)).

Case 3: an offset between a center frequency of the CORESET and a centerfrequency of the synchronization signal block is M 15 kHz subcarriers;that is, an absolute offset between the center frequencies isM×SC_(SSB).

Case 4: a high frequency boundary of the CORESET is lower than a lowfrequency boundary of the synchronization signal block by M 15 kHzsubcarriers; and in this case, an offset between a center frequency ofthe CORESET and a center frequency of the synchronization signal blockis (BW_(CORESET)+BW_(SSB))/2+M×SC_(SSB).

Case 5: a low frequency boundary of the CORESET is higher than a highfrequency boundary of the synchronization signal block by12×SC_(CORESET)−M×SC_(SSB); and in this case, an offset between a centerfrequency of the CORESET and a center frequency of the synchronizationsignal block is (BW_(CORESET)+BW_(SSB))/2+(12×SC_(CORESET)−M×SC_(SSB));

-   -   where M is a number of synchronization signal block subcarriers        in a frequency domain offset between the synchronization signal        block and a PRB boundary, M is an integer, and when the        subcarrier spacing of the CORESET is less than or equal to the        subcarrier spacing of the synchronization signal block, a range        of the value of the offset is: 0≤M≤11. When the subcarrier        spacing of the CORESET is greater than the subcarrier spacing of        the synchronization signal block, the range of the value of the        offset is: 0≤M≤23. SC_(CORESET) is a frequency domain width of a        control resource set subcarrier, SC_(SSB) is a frequency domain        width of a synchronization signal block subcarrier, BW_(CORESET)        is the control resource set bandwidth, and BW_(SSB) is the        synchronization signal block bandwidth.

In the foregoing 5 cases, in the cases 1, 2 and 3, the frequency domainrange of the CORESET includes the frequency domain range of thesynchronization signal block; and in the cases 4 and 5, the frequencydomain range of the CORESET does not overlap the frequency domain rangeof the synchronization signal block.

Sub-Implementation Manner 2.2:

FIGS. 7, 9 and 11 illustrate cases where the offset (offset) is anoffset between a physical resource block PRB boundary of thesynchronization signal block and a PRB boundary of a carrier at a higherfrequency, and there are the following case 1 to case 5 similar to thecases illustrated in FIG. 6 .

Case 1: a low frequency boundary of the CORESET is lower than a lowfrequency boundary of the synchronization signal block by12×SC_(CORESET)−M×SC_(SSB); and in this case, an offset between a centerfrequency of the CORESET and a center frequency of the synchronizationsignal block is (BW_(CORESET)−BW_(SSB))/2−(12×SC_(CORESET)−M×SC_(SSB)).

Case 2: a high frequency boundary of the CORESET is higher than a highfrequency boundary of the synchronization signal block by M×SC_(SSB),that is, M synchronization signal block subcarriers; and in this case,an offset between a center frequency of the CORESET and a centerfrequency of the synchronization signal block is(BW_(CORESET)−BW_(SSB))/2−M×SC_(SSB).

Case 3: an offset between a center frequency of the CORESET and a centerfrequency of the synchronization signal block is M 15 kHz subcarriers;that is, an absolute offset between the center frequencies isM×SC_(SSB).

Case 4: a high frequency boundary of the CORESET is lower than a lowfrequency boundary of the synchronization signal block by12×SC_(CORESET)−M×SC_(SSB); and in this case, an offset between a centerfrequency of the CORESET and a center frequency of the synchronizationsignal block is (BW_(CORESET)+BW_(SSB))/2+(12×SC_(CORESET)−M×SC_(SSB)).

Case 5: a low frequency boundary of the CORESET is higher than a highfrequency boundary of the synchronization signal block by M×SC_(SSB),that is, M synchronization signal block subcarriers; and in this case,an offset between a center frequency of the CORESET and a centerfrequency of the synchronization signal block is(BW_(CORESET)+BW_(SSB))/2+M×SC_(SSB).

Where M is a number of synchronization signal block subcarriers in afrequency domain offset between the synchronization signal block and aPRB boundary, M is an integer, and when the subcarrier spacing of theCORESET is less than or equal to the subcarrier spacing of thesynchronization signal block, a range of the value of the offset is:0≤M≤11. When the subcarrier spacing of the CORESET is greater than thesubcarrier spacing of the synchronization signal block, the range of thevalue of the offset is: 0≤M≤23. SC_(CORESET) is a frequency domain widthof a control resource set subcarrier, SC_(SSB) is a frequency domainwidth of a synchronization signal block subcarrier, BW_(CORESET) is thecontrol resource set bandwidth, and BW_(SSB) is the synchronizationsignal block bandwidth.

In the foregoing 5 cases, in the cases 1, 2 and 3, the frequency domainrange of the CORESET includes the frequency domain range of thesynchronization signal block; and in the cases 4 and 5, the frequencydomain range of the CORESET does not overlap with the frequency domainrange of the synchronization signal block.

In the CORESET frequency domain positions as above, any one or moreoptional positions thereof may be specified in the protocol, and anindication bit is introduced into a CORESET configuration informationindication field of the PBCH to indicate a frequency domain position ofthe CORESET of a current carrier to a terminal. For example, it isspecified in the protocol that the frequency domain position of theCORESET includes the following 4 cases: case 1, case 2, case 4 and case5; and 2 bits are used in the PBCH to indicate which configuration ofthe foregoing 4 frequency domain positions is currently used.

Alternatively, as defined below, in the case 1 and case 2, the CORESETbandwidth overlaps the synchronization signal block bandwidth, and it ismore suitable for a case that the subcarrier spacing of both is thesame; on the contrary, in the case 4 and case 5, the CORESET bandwidthdoes not overlap the synchronization signal block bandwidth, and it ismore suitable for a case that the subcarrier spacing of both isdifferent. Therefore, it is specified in the protocol that when thesubcarrier spacing of the CORESET and the subcarrier spacing of thesynchronization signal block are the same, 1 bit is introduced into thePBCH to indicate which configuration of the foregoing frequency domainpositions in the case 1 and case 2 is currently used; and when thesubcarrier spacing of the CORESET and the subcarrier spacing of thesynchronization signal block are different, 1 bit is introduced into thePBCH to indicate which configuration of the foregoing frequency domainpositions in the case 4 and case 5 is currently used.

Implementation Manner 3:

The present implementation manner describes indication manners forinformation of a slot in which a control resource set is located.

There are three following cases for the information of the slot in whichthe CORESET is located.

Case 1: the CORESET is transmitted in a slot containing asynchronization signal block (as shown in (a) of FIG. 12 , FIG. 12 is aschematic structural diagram that a CORESET is transmitted in a slot inwhich a synchronization signal block (Synchronization Signal Block, SSB)is located according to the present embodiment: that is, twosynchronization signal blocks SSB1, SSB2 are included in one slot, andrespectively corresponding CORESETs are in a symbol previous to a symboloccupied by the SSBs).

Case 2: the CORESET is transmitted in a slot containing asynchronization signal block and transmitted in a slot not containingthe synchronization signal block (as shown in (b) of FIG. 12 , it is aschematic structural diagram that a CORESET is transmitted in a slot inwhich an SSB is located and transmitted in a slot not containing thesynchronization signal block: that is, two synchronization signal blocksSSB1, SSB2 are included in one slot, a CORESET corresponding to the SSB2is in a symbol previous to a symbol occupied by the SSB, and a CORESETcorresponding to the SSB1 is transmitted in a slot not containing theSSB).

Case 3: the CORESET is transmitted in a slot not containing asynchronization signal block (as shown in (c) of FIG. 12 , it is aschematic structural diagram that a CORESET is transmitted in a slot notcontaining a synchronization signal block: that is, in one slot notcontaining an SSB, CORESETs are mapped to the first and seventh symbolsin the slot, respectively).

As shown in FIG. 13 , there is another form for the transmission of thecontrol resource set in a slot containing a synchronization signalblock, that is, a plurality of synchronization signal block transmissionperiods are used. FIG. 13 is a schematic diagram of use of a pluralityof synchronization signal block transmission periods according to thepresent embodiment (in FIG. 13 , SS burst set periodicity refers to atransmission period of synchronization signal blocks). Twosynchronization signal blocks are mapped in one slot (slot), a CORESET1corresponding to a former SSB is transmitted in a slot in which an SSB1is located in a first period, and a CORESET2 corresponding to a latterSSB is transmitted in a slot in which an SSB2 is located in a secondperiod. In this case, the transmission period of the CORESET is twicethat of the SSBs.

That CORESETs corresponding to which SSBs are transmitted in which SSburst set period may be predefined by a system, for example, an oddnumber of CORESETs corresponding to SSBs are included on a radio framewith a system frame number SFN mode 4=0; and an even number of CORESETscorresponding to SSBs are included on a radio frame with a SFN mode 4=2.Alternatively, an odd number of CORESETs corresponding to SSBs areincluded on a radio frame with a SFN mode 4=0 or 1; and an even numberof CORESETs corresponding to SSBs are included on a radio frame with aSFN mode 4=2 or 3.

An indication bit may be introduced into a CORESET configurationinformation indication field of the PBCH to indicate information of aslot in which the CORESET of a current carrier is located to theterminal. For example, 2 bits are used for indication, ‘00’ represents‘the control resource set is transmitted in a slot containing asynchronization signal block’, ‘01’ represents ‘the control resource setis transmitted in a slot containing a synchronization signal block andalso transmitted in a slot not containing the synchronization signalblock’, ‘10’ represents ‘the control resource set is transmitted in aslot not containing a synchronization signal block’, and ‘11’ represents‘a manner of CORESET transmission spanning periods (corresponding toFIG. 13 )’.

Alternatively, 1 bit is used for indication, ‘0’ represents ‘the controlresource set is transmitted in a slot containing a synchronizationsignal block, and ‘1’ represents ‘the control resource set istransmitted only in a slot not containing a synchronization signalblock’. In this case, ‘0’ actually contains three cases shown in (a) ofFIG. 12 , (b) of FIG. 12 and FIG. 13 .

Alternatively, 1 bit is used for indication, ‘0’ represents ‘the controlresource set is transmitted only in a slot containing a synchronizationsignal block; and ‘1’ represents ‘the control resource set istransmitted in a slot not containing a synchronization signal block’. Inthis case, ‘0’ actually contains two cases shown in (a) of FIG. 12 andFIG. 13 ; and ‘1’ actually contains two cases shown in (b) of FIG. 12and (c) of FIG. 12 .

Alternatively, it is specified in the protocol that any two of theforegoing four cases are contained, and 1 bit is further used in thePBCH to indicate which configuration is particularly used for a currentcarrier.

Implementation Manner 4:

The present implementation manner describes indication manners forposition information of a symbol occupied by the CORESET in a slot;where the position information of the symbol occupied by the CORESET inthe slot includes: a starting symbol index of the symbol occupied by theCORESET in the slot and a number of symbols occupied by the CORESET inthe slot.

As shown in FIG. 14 , FIG. 14 is a schematic diagram of mapping patternsof a current synchronization signal block (SSB) to a slot according thepresent embodiment, where (a) of FIG. 14 is applied to mapping ofsynchronization signal blocks with subcarrier spacing of 15 kHz or 30kHz (pattern 2) to a slot; (b) of FIG. 14 is applied to mapping ofsynchronization signal blocks with subcarrier spacing of 30 kHz(pattern 1) or 120 kHz to a slot; and (c) of FIG. 14 is applied tomapping of synchronization signal blocks with subcarrier spacing of 240kHz to a slot. The slots in (a) of FIG. 14 and (b) of FIG. 14 are slotscorresponding to subcarrier spacing of current synchronization signalblocks; and the slot in (c) of FIG. 14 corresponds to a slot of 120 kHz.

Sub-Implementation Manner 4.1:

For the mapping of the synchronization signal blocks of 15 kHz or 30 kHz(pattern 2) shown in (a) of FIG. 14 , FIG. 15 is a schematic diagram Iof position information of a symbol occupied by a CORESET in a slotaccording to the present embodiment. As shown in FIG. 15 , the positioninformation of the symbol occupied by the CORESET includes one or moreof the following, where an arrow starting from an SSB points to aCORESET corresponding thereto.

In a configuration of FIG. 15 (1), each CORESET occupies 1 symbol, andis mapped in a same slot, and an SSB particularly occupies one symbolbefore the SSB, that is, a CORESET corresponding to the first SSB in theslot occupies the second symbol in the slot, and a CORESET correspondingto the second SSB in the slot occupies the eighth symbol in the slot.

In a configuration of FIG. 15 (2), each CORESET occupies 1 symbol, and aCORESET corresponding to the first SSB in the slot is mapped to theeighth symbol of a slot outside a 5 ms SSB time window; and a CORESETcorresponding to the second SSB in the slot is mapped in the slot inwhich the SSB is located, and particularly occupies 1 symbol before theSSB, that is, the eighth symbol in the slot.

In a configuration of FIG. 15 (3), each CORESET occupies 1 symbol, and aCORESET corresponding to the first SSB in the slot is mapped in the slotin which the SSB is located, and particularly occupies 1 symbol beforethe SSB, that is, the second symbol in the slot; and a CORESETcorresponding to the second SSB in the slot is mapped to the secondsymbol of a slot outside a 5 ms SSB time window.

In a configuration of FIG. 15 (4), each CORESET occupies 1 symbol, andis mapped in the slot in which an SSB is located, and the SSBparticularly occupies first two symbols in the slot, that is, a CORESETcorresponding to the first SSB in the slot occupies the first symbol inthe slot, and a CORESET corresponding to the second SSB in the slotoccupies the second symbol in the slot.

In a configuration of FIG. 15 (5), each CORESET occupies 2 symbols, anda CORESET corresponding to the first SSB in the slot is mapped in theslot in which the SSB is located, and particularly occupies first twosymbols of the slot in which the SSB is located; and a CORESETcorresponding to the second SSB in the slot is mapped to the first andsecond symbols of a slot outside a 5 ms SSB time window.

In a configuration of FIG. 15 (6), each CORESET occupies 2 symbol, and aCORESET corresponding to the first SSB in the slot is mapped to theseventh and eighth symbols of a slot outside a 5 ms SSB time window; anda CORESET corresponding to the second SSB in the slot is mapped in theslot in which the SSB is located, and particularly occupies the seventhand eighth symbols of the slot in which the SSB is located.

In a configuration of FIG. 15 (7), each CORESET occupies 2 symbol, and aCORESET corresponding to the first SSB in the slot is mapped to thefirst and second symbols of a slot outside a 5 ms SSB time window; and aCORESET corresponding to the second SSB in the slot is mapped in theslot in which the SSB is located, and particularly occupies the seventhand eighth symbols of the slot in which the SSB is located.

In a configuration of FIG. 15 (8), each CORESET occupies 2 symbol, andis mapped in a same slot, and an SSB particularly occupies two symbolsbefore the SSB, that is, a CORESET corresponding to the first SSB in theslot occupies the first and second symbols in the slot, and a CORESETcorresponding to the second SSB in the slot occupies the seventh andeighth symbols in the slot.

In a configuration of FIG. 15 (9), each CORESET occupies 1 or 2 or 3 or4 symbols, a multiplexing manner of frequency-division multiplexing(Frequency-division multiplexing, FDM) is used for CORESETs andcorresponding SSBs, that is, a CORESET corresponding to the first SSB inthe slot is mapped in the slot in which the SSB is located. In anembodiment, when a CORESET occupies 1 symbol, it occupies the thirdsymbol of a slot in which an SSB is located; for 2 symbols of a CORESET,the third and fourth symbols are occupied; for 3 symbols of a CORESET,the third, fourth and fifth symbols are occupied; for 4 symbols of aCORESET, the third, fourth, fifth and sixth symbols are occupied; and aCORESET corresponding to the second SSB in the slot is mapped in theslot in which the SSB is located. In an embodiment, when a CORESEToccupies 1 symbol, it occupies the ninth symbol of a slot in which anSSB is located; for 2 symbols of a CORESET, the ninth and tenth symbolsare occupied; for 3 symbols of a CORESET, the ninth, tenth and eleventhsymbols are occupied; for 4 symbols of a CORESET, the ninth, tenth,eleventh and twelfth symbols are occupied; and a recourse other than anSSB is occupied in frequency domain.

In a configuration of FIG. 15 (10), each CORESET occupies 1 or 2 or 3 or4 symbols, a multiplexing manner of FDM is used for CORESETs andcorresponding SSBs, that is, a CORESET corresponding to the first SSB inthe slot is mapped in the slot in which the SSB is located. In anembodiment, when a CORESET occupies 1 symbol, it occupies the thirdsymbol of a slot in which an SSB is located; for 2 symbols of a CORESET,the third and fourth symbols are occupied; for 3 symbols of a CORESET,the third, fourth and fifth symbols are occupied; for 4 symbols of aCORESET, the third, fourth, fifth and sixth symbols are occupied; and aCORESET corresponding to the second SSB in the slot is mapped to a slotoutside a 5 ms SSB time window. In an embodiment, when a CORESEToccupies 1 symbol, it occupies the third symbol of a slot in which anSSB is located; for 2 symbols of a CORESET, the third and fourth symbolsare occupied; for 3 symbols of a CORESET, the third, fourth and fifthsymbols are occupied; and for 4 symbols of a CORESET, the third, fourth,fifth and sixth symbols are occupied. A resource other than a frequencydomain resource corresponding to an SSB is occupied in frequency domain.

Sub-Implementation Manner 4.2:

For the mapping of the synchronization signal blocks of 30 kHz(pattern 1) or 120 kHz shown in (b) of FIG. 14 , a mapping resourceconfiguration is performed based on 2 slots and 4 SSBs as a period. FIG.16 is a schematic diagram II of position information of a symboloccupied by a CORESET in a slot according to the present embodiment. Asshown in FIG. 16 , the position information of the symbol occupied bythe CORESET includes one or more of the following, where an arrowstarting from an SSB points to a CORESET corresponding thereto.

In a configuration of FIG. 16 (1), each CORESET occupies 1 symbol, wherea CORESET of the first SSB occupies the third symbol in a former slot; aCORESET of the second SSB occupies the fourth symbol in the former slot;a CORESET of the third SSB occupies the first symbol in a latter slot;and a CORESET of the fourth SSB occupies the second symbol in the latterslot.

In a configuration of FIG. 16 (2), each CORESET occupies 1 symbol, wherea CORESET of the first SSB occupies the third symbol in a former slot; aCORESET of the second SSB occupies the fourth symbol in the former slot;a CORESET of the third SSB occupies the third symbol in a slot outside a5 ms SSB time window; a CORESET of the fourth SSB occupies the fourthsymbol in the slot outside a 5 ms SSB time window; and ‘spacing betweenthe CORESET of the first SSB and the CORESET of the third SSB’ is equalto “spacing between the CORESET of the second SSB and the CORESET of thefourth SSB”, for example, the spacing is equal to 5 ms.

In a configuration of FIG. 16 (3), each CORESET occupies 1 symbol, wherea CORESET of the first SSB occupies the fourth symbol in a former slot;a CORESET of the second SSB occupies the fourth symbol of a slot outsidea 5 ms SSB time window; a CORESET of the third SSB occupies the fourthsymbol in a latter slot; a CORESET of the fourth SSB occupies the secondsymbol in the slot outside a 5 ms SSB time window; and ‘spacing betweenthe CORESET of the first SSB and the CORESET of the third SSB’ is equalto “spacing between the CORESET of the second SSB and the CORESET of thefourth SSB”, for example, the spacing is equal to 5 ms.

In a configuration of FIG. 16 (4), each CORESET occupies 1 symbol, andCPRESETs are mapped to the first 4 symbols in a first slot,respectively. In an embodiment, a CORESET of the first SSB occupies thefirst symbol in a former slot; a CORESET of the second SSB occupies thesecond symbol in the former slot; a CORESET of the third SSB occupiesthe third symbol in the former slot; and a CORESET of the fourth SSBoccupies the fourth symbol in the former slot.

In a configuration of FIG. 16 (5), each CORESET occupies 2 symbols,where a CORESET of the first SSB occupies the first and second symbolsin a former slot; a CORESET of the second SSB occupies the third andfourth symbols in the former slot; a CORESET of the third SSB occupiesthe first and second symbols in a slot outside a 5 ms SSB time window; aCORESET of the fourth SSB occupies the third and fourth symbols in theslot outside a 5 ms SSB time window; and ‘time domain spacing betweenthe CORESET of the first SSB and the CORESET of the third SSB’ is equalto “time domain spacing between the CORESET of the second SSB and theCORESET of the fourth SSB”, for example, the spacing is equal to 5 ms.

In a configuration of FIG. 16 (6), each CORESET occupies 2 symbols,where a CORESET of the first SSB occupies the third and fourth symbolsin a former slot; a CORESET of the second SSB occupies the first andsecond symbols in a latter slot; a CORESET of the third SSB occupies hethird and fourth symbols in a slot outside a 5 ms SSB time window; aCORESET of the fourth SSB occupies he first and second symbols in theslot outside a 5 ms SSB time window; and ‘time domain spacing betweenthe CORESET of the first SSB and the CORESET of the third SSB’ is equalto “time domain spacing between the CORESET of the second SSB and theCORESET of the fourth SSB”, for example, the spacing is equal to 5 ms.

In a configuration of FIG. 16 (7), each CORESET occupies 2 symbols,where a CORESET of the first SSB occupies the first and second symbolsin a former slot; a CORESET of the second SSB occupies the third andfourth symbols in the former slot; a CORESET of the third SSB occupiesthe first and second symbols in a latter slot; a CORESET of the fourthSSB occupies the first and second symbols in a slot outside a 5 ms SSBtime window; and ‘time domain spacing between the CORESET of the firstSSB and the CORESET of the fourth SSB’ is equal to 5 ms.

In a configuration of FIG. 16 (8), each CORESET occupies 2 symbols,where a CORESET of the first SSB occupies the first and second symbolsin a former slot; a CORESET of the second SSB occupies the third andfourth symbols in the former slot; a CORESET of the third SSB occupiesthe first and second symbols in a former slot; a CORESET of the fourthSSB occupies the first and second symbols in a slot outside a 5 ms SSBtime window; and ‘time domain spacing between the CORESET of the secondSSB and the CORESET of the fourth SSB’ is equal to 5 ms, or ‘time domainspacing between the CORESET of the third SSB and the CORESET of thefourth SSB’ is equal to 5 ms.

In a configuration of FIG. 16 (9), each CORESET occupies 1 or 2 or 3 or4 symbols, a multiplexing manner of FDM is used for CORESETs andcorresponding SSBs, that is:

a CORESET corresponding to the first SSB is mapped in a slot in whichthe SSB is located. In an embodiment, when a CORESET occupies 1 symbol,it occupies the fifth symbol of a slot in which an SSB is located; fortwo symbols of a CORESET, the fifth and sixth symbols are occupied; forthree symbols of a CORESET, the fifth, sixth and seventh symbols areoccupied; for four symbols of a CORESET, the fifth, sixth, seventh andeighth symbols are occupied; and a recourse other than an SSB isoccupied in frequency domain.

A CORESET corresponding to the second SSB is mapped in a slot in whichthe SSB is located. In an embodiment, when a CORESET occupies 1 symbol,it occupies the ninth symbol of a slot in which an SSB is located; fortwo symbols of a CORESET, the ninth and tenth symbols are occupied; forthree symbols of a CORESET, the ninth, tenth and eleventh symbols areoccupied; for four symbols of a CORESET, the ninth, tenth, eleventh andtwelfth symbols are occupied; and a recourse other than an SSB isoccupied in frequency domain.

A CORESET corresponding to the third SSB is mapped in a slot in whichthe SSB is located. In an embodiment, when a CORESET occupies onesymbol, it occupies the third symbol of a slot in which an SSB islocated; for two symbols of a CORESET, the third and fourth symbols areoccupied; for three symbols of a CORESET, the third, fourth and fifthsymbols are occupied; for four symbols of a CORESET, the third, fourth,fifth and sixth symbols are occupied; and a recourse other than an SSBis occupied in frequency domain.

A CORESET corresponding to the fourth SSB is mapped in a slot in whichthe SSB is located. In an embodiment, when a CORESET occupies 1 symbol,it occupies the seventh symbol of a slot in which an SSB is located; fortwo symbols of a CORESET, the seventh and eighth symbols are occupied;for three symbols of a CORESET, the seventh, eighth and ninth symbolsare occupied; for four symbols of a CORESET, the seventh, eighth, ninthand tenth symbols are occupied; and a recourse other than an SSB isoccupied in frequency domain.

In a configuration of FIG. 16 (10), each CORESET occupies 1 or 2 or 3 or4 symbols, a multiplexing manner of FDM is used for CORESETs andcorresponding SSBs, that is:

a CORESET corresponding to the first SSB is mapped in a slot in whichthe SSB is located. In an embodiment, when a CORESET occupies 1 symbol,it occupies the fifth symbol of a slot in which an SSB is located; fortwo symbols of a CORESET, the fifth and sixth symbols are occupied; forthree symbols of a CORESET, the fifth, sixth and seventh symbols areoccupied; for four symbols of a CORESET, the fifth, sixth, seventh andeighth symbols are occupied; and a recourse other than an SSB isoccupied in frequency domain.

A CORESET corresponding to the second SSB is mapped in a slot outside a5 ms time window. In an embodiment, when a CORESET occupies 1 symbol, itoccupies the fifth symbol; for two symbols of a CORESET, the fifth andsixth symbols are occupied; for three symbols of a CORESET, the fifth,sixth and seventh symbols are occupied; for four symbols of a CORESET,the fifth, sixth, seventh and eighth symbols are occupied; and arecourse other than a frequency domain resource corresponding to an SSBis occupied in frequency domain. in addition, ‘spacing between theCORESET of the first SSB and the CORESET of the third SSB’ is equal to 5ms.

A CORESET corresponding to the third SSB is mapped in a slot in whichthe SSB is located. In an embodiment, when a CORESET occupies 1 symbol,it occupies the third symbol of a slot in which an SSB is located; fortwo symbols of a CORESET, the third and fourth symbols are occupied; forthree symbols of a CORESET, the third, fourth and fifth symbols areoccupied; for four symbols of a CORESET, the third, fourth, fifth andsixth symbols are occupied; and a recourse other than an SSB is occupiedin frequency domain.

A CORESET corresponding to the fourth SSB is mapped in a slot outside a5 ms time window. In an embodiment, when a CORESET occupies 1 symbol, itoccupies the seventh symbol; for two symbols of a CORESET, the seventhand eighth symbols are occupied; for three symbols of a CORESET, theseventh, eighth, and ninth symbols are occupied; for four symbols of aCORESET, the seventh, eighth, ninth and tenth symbols are occupied; anda recourse other than a frequency domain resource corresponding to anSSB is occupied in frequency domain. In addition, ‘spacing between theCORESET of the second SSB and the CORESET of the fourth SSB’ is equal to5 ms.

Sub-Implementation Manner 4.3:

When a CORESET is mapped only to a slot outside an SSB, FIG. 17 is aschematic diagram I that a CORESET is mapped to a slot outside an SSBaccording to the present embodiment, and FIG. 18 is a schematic diagramII that a CORESET is mapped to a slot outside an SSB according to thepresent embodiment. As shown in FIGS. 17 and 18 , position informationof a symbol occupied by the CORESET in a slot includes one or more ofthe following.

In a configuration of FIG. 17 (1), a slot includes 2 CORESETs, each ofthe CORESETs occupies 1 symbol, and the CORESETs are located on thefirst and second symbols in the slot, respectively.

In a configuration of FIG. 17 (2), a slot includes 2 CORESETs, each ofthe CORESETs occupies 2 symbols. In an embodiment, one CORESET is mappedto the first and second symbols in the slot, and the other CORESET ismapped to the third and fourth symbols in the slot.

In a configuration of FIG. 17 (3), a slot includes 2 CORESETs, each ofthe CORESETs occupies 1 symbol, and the CORESETs are located on thefirst and eighth symbols in the slot, respectively.

In a configuration of FIG. 17 (4), a slot includes 2 CORESETs, each ofthe CORESETs occupies 2 symbols. In an embodiment, one CORESET is mappedto the first and second symbols in the slot, and the other CORESET ismapped to the eighth and ninth symbols in the slot.

In a configuration of FIG. 17 (5), a slot includes 2 CORESETs, each ofthe CORESETs occupies 1 symbol, and the CORESETs are located on thethird and ninth symbols in the slot, respectively.

In a configuration of FIG. 17 (6), a slot includes 2 CORESETs, each ofthe CORESETs occupies 2 symbols. In an embodiment, one CORESET is mappedto the third and fourth symbols in the slot, and the other CORESET ismapped to the ninth and tenth symbols in the slot.

In a configuration of FIG. 17 (7), a slot includes 1 CORESET, whichoccupies 1 symbol. In an embodiment, the CORESET is mapped to the firstsymbol in the slot.

In a configuration of FIG. 17 (8), a slot includes 1 CORESET, whichoccupies 2 symbols. In an embodiment, the CORESET is mapped to the firstand second symbols in a slot.

In a configuration of FIG. 18 (1), with two slots as a configurationperiod, 4 CORESETs are included, and each CORESET includes 1 symbol: thefirst CORESET is mapped to the fifth symbol of a former slot, the secondCORESET is mapped to the ninth symbol of the former slot, the thirdCORESET is mapped to the third symbol of a latter slot, and the fourthCORESET is mapped to the the seventh symbol of the latter slot.

In a configuration of FIG. 18 (2), with two slots as a configurationperiod, 4 CORESETs are included, and each CORESET includes 2 symbols:the first CORESET is mapped to the fifth and sixth symbols of a formerslot, the second CORESET is mapped to the ninth and tenth symbols of theformer slot, the third CORESET is mapped to the third and fourth symbolsof a latter slot, and the fourth CORESET is mapped to the seventh andeighth symbols of the latter slot.

In the foregoing configurations, a position of a symbol occupied by acurrently used CORESET in a slot may be indicated to a terminal by thefollowing manners.

According to the CORESET bandwidth configuration described in theimplementation manner 1, the terminal can determine the bandwidth of thecurrent CORESET, and when the CORESET bandwidth takes the minimumchannel bandwidth, since the bandwidth value is relatively small, amanner of time-division multiplexing for CORESETs and SSBs is preferred.

Conversely, when the CORESET bandwidth takes a larger value, that is,the minimum UE bandwidth, a manner of frequency-division multiplexingfor CORESETs and SSBs is preferred.

In addition, according to the manner described in the implementationmanner 3, the terminal can determine the information of the slot inwhich the CORESET is located.

The following 3 tables, Table 1, Table 2, and Table 3, are defined.

Table 1 is applicable to a case that the CORESET bandwidth is configuredas ‘minimum channel bandwidth’, and information of a slot in which theCORESET is located is ‘the control resource set is transmitted in a slotcontaining a synchronization signal block’; and in a PBCH, 3 bitsparticularly indicate to a terminal which of the eight configurations inTable 1 is used.

Table 2 is applicable to a case that the CORESET bandwidth takes agreater value, that is, ‘minimum UE bandwidth’, and information of aslot in which the CORESET is located is ‘the control resource set istransmitted in a slot containing a synchronization signal block’; and ina PBCH, 3 bits particularly indicate to a terminal which of the eightconfigurations in Table 2 is used.

Table 3 is applicable to a case that information of a slot in which theCORESET is located is ‘the control resource set is transmitted in a slotnot containing a synchronization signal block’; or subcarrier spacing ofthe CORESET and subcarrier spacing of the synchronization signal blockare different, and then the CORESET and the synchronization signal blockbelong to different bandwidth parts (Bandwidth Parts, BWP); and in aPBCH, 3 bits particularly indicate to a terminal which of the eightconfigurations in Table 3 is used.

TABLE 1 Number of CORESET OFDM Index Symbols 15 kHz/30 kHz (pattern 2)30 kHz (pattern 1)/120 kHz 000 1 Configuration of FIG. 15 (1)Configuration of FIG. 16 (1) 001 1 Configuration of FIG. 15 (2)Configuration of FIG. 16 (2) 010 1 Configuration of FIG. 15 (3)Configuration of FIG. 16 (3) 011 1 Configuration of FIG. 15 (4)Configuration of FIG. 16 (4) 100 2 Configuration of FIG. 15 (5)Configuration of FIG. 16 (5) 101 2 Configuration of FIG. 15 (6)Configuration of FIG. 16 (6) 110 2 Configuration of FIG. 15 (7)Configuration of FIG. 16 (7) 111 2 Configuration of FIG. 15 (8)Configuration of FIG. 16 (8)

TABLE 2 Number of CORESET OFDM Index Symbols 15 kHz/30 kHz (pattern 2)30 kHz (pattern 1)/120 kHz 000 1 Configuration of FIG. 15(9)Configuration of FIG. 16(9) 001 2 010 3 011 4 100 1 Configuration ofFIG.15(10) Configuration of FIG. 16(10) 101 2 110 3 111 4

TABLE 3 Number of CORESET OFDM Index Symbols 15 kHz/30 kHz (pattern 2)30 kHz (pattern 1)/120 kHz 000 1 Configuration of FIG. 17(1) 001 2Configuration of FIG. 17(2) 010 1 Configuration of FIG. 17(3) 011 2Configuration of FIG. 17(4) 100 1 Configuration of FIG. 17(5)Configuration of FIG. 18(1) 101 2 Configuration of FIG. 17(6)Configuration of FIG. 18(2) 110 1 Configuration of FIG. 17(7) 111 2Configuration of FIG. 17(8)

Implementation Manner 5:

The present implementation manner describes an indication manner of theCORESET monitoring window (PDCCH monitoring window) configurationinformation.

The CORESET monitoring window configuration information includes atleast one of the following information: a monitoring period of theCORESET, a starting position of the monitoring window, time domainduration of a monitoring window, and a time domain offset betweenadjacent monitoring windows.

The CORESET monitoring window is also referred to as a physical downlinkcontrol channel PDCCH monitoring window, each monitoring windowcorresponds to a synchronization signal block, and a monitoring windowof the CORESET includes one or more CORESET monitoring opportunities,that is, one or more resources for transmitting a PDCCH. A base stationselects one PDCCH transmission resource in a CORESET monitoring windowfor PDCCH transmission, and a terminal may attempt to receive a PDCCHcorresponding to the synchronization signal block on one or more PDCCHtransmission resources in the CORESET monitoring window. There is aquasi-co-location (Quasi-co-location, QCL) relationship between thesynchronization signal block and the CORESET or PDCCH in thecorresponding monitoring window.

The monitoring period of the CORESET may also be understood as atransmission period of the CORESET, and a value of the period may bepredefined, for example, as 40 ms. It is also possible to predefinevalues of a plurality of monitoring periods in the protocol, such as 20ms, 40 ms, and in a PBCH, a particular value of a monitoring period of acurrent carrier is indicated by 1 bit.

The starting position of the monitoring window of the CORESET refers toa time domain starting position of the first CORESET monitoring window;and with 20 ms of the CORESET transmission period as an example, whenthe CORESET is transmitted in a slot containing a synchronization signalblock, the CORESET starting position of the monitoring window ispredefined. FIG. 19 is a schematic diagram that a CORESET is transmittedin a slot containing a synchronization signal block according thepresent embodiment, and as shown in FIG. 19 , a starting position of themonitoring window of a CORESET is a starting point of a radio frame withSFN mod 2=0.

When the CORESET is transmitted in a slot not containing asynchronization signal block, the CORESET starting position of themonitoring window is predefined. FIG. 20 is a schematic diagram that aCORESET is transmitted in a slot not containing a synchronization signalblock according the present embodiment, and as shown in FIG. 20 , astarting position of the monitoring window of a CORESET is the sixthsubframe (that is, the second half frame) of a radio frame with SFN mod2=0.

When the CORESET is transmitted in a slot containing a synchronizationsignal block and also transmitted in a slot not containing thesynchronization signal block, FIG. 21 is a schematic diagram that aCORESET is transmitted in a slot containing a synchronization signalblock and also transmitted in a slot not containing the synchronizationsignal block according the present embodiment (as shown in FIG. 21 , fora CORESET transmitted in a slot in which a synchronization signal blockis located, a starting position of the monitoring window thereof is astarting point of a radio frame with SFN mod 2=0; and for a CORESETtransmitted in a slot not containing a synchronization signal block, astarting position of the monitoring window thereof is the sixthsub-frame (that is, the second half frame) of a radio frame with SFN mod2=0).

The time domain duration of the monitoring window of the CORESET is oneor more slots; for example, the time domain duration of the monitoringwindow is one or more of the following: 1 slot, 2 slots, 4 slots, or Mslots, where M is a number of slots occupied by synchronization signalblocks in a synchronization signal block transmission period.

When the CORESET is transmitted in a slot in which a synchronization islocated, the time domain duration of the monitoring window is 1 slot;and when the CORESET is transmitted in a slot not containing asynchronization signal block, the time domain duration of the monitoringwindow may be one or more slots.

An indication bit may be introduced into in a CORESET configurationinformation indication field of the PBCH to indicate time domainduration of the CORESET monitoring window of a current carrier to theterminal. For example, 2 bits are used for indication, ‘00’ represents‘the time domain duration of the monitoring window is 1 slot’, ‘01’represents ‘the time domain duration of the monitoring window is 2slots’, ‘10’ represents ‘the time domain duration of the monitoringwindow is M slots’, and ‘11’ represents ‘state reservation’.

Alternatively, it is specified in the protocol that only any two of theforegoing 4 types of the time domain duration of the CORESET monitoringwindow are included, and 1 bit is further used in the PBCH to indicatewhich configuration is particularly used for a current carrier; forexample, ‘0’ represents ‘the time domain duration of the monitoringwindow is 1 slot’, and ‘1’ represents ‘the time domain duration of themonitoring window is 2 slots’.

Alternatively, it is specified in the protocol that the time domainduration of the CORESET monitoring window may be configured in one ofthe following three types: 1 slot, 2 slots, and 4 slots; and time domaintransmission resources of the CORESET monitoring window and the timedomain duration of the monitoring window are jointly indicated, and 2bits are occupied in total, for example,

‘00’: the CORESET is transmitted in a slot containing an SS/PBCH block,and the CORESET monitoring window length is equal to 1 slot;

‘01’: the CORESET is transmitted in a slot not containing an SS/PBCHblock, and the CORESET monitoring window length is equal to 1 slot;

‘10’: the CORESET is transmitted in a slot not containing an SS/PBCHblock, and the CORESET monitoring window length is equal to 2 slots;

‘11’: the CORESET is transmitted in a slot not containing an SS/PBCHblock, and the CORESET monitoring window length is equal to 4 slots; andan time domain offset between adjacent monitoring windows includes oneor more of the following: 0, the time domain duration of the monitoringwindow, and 1/X of the time domain duration of the monitoring window,where X is an integer greater than 1, and a value thereof may bepredefined in a protocol or indicated by a signaling.

FIG. 22 is a schematic diagram that a CORESET is transmitted in a slotin which a synchronization signal block is located according the presentembodiment. As shown in FIG. 22 , when the CORESET is transmitted in aslot in which a synchronization signal block is located, and the CORESETand a corresponding SSB are frequency-division multiplexed andtransmitted, time domain duration of a monitoring window is 1 slot, anda time domain offset between adjacent monitoring windows is equal to thetime domain duration of the monitoring window, that is, 1 slot. In thiscase, there is no overlap between the adjacent monitoring windows. InFIG. 22 , 8 synchronization signal blocks included can be used asresources for transmitting a synchronization signal and a physicalbroadcast channel, and a base station can select some or all of them asactually transmitted synchronization signal blocks (actual SSBs).

FIG. 23 is a schematic diagram I that a CORESET is transmitted in a slotnot containing a synchronization signal block according the presentembodiment. In FIG. 23 , the CORESET is transmitted in a slot notcontaining a synchronization signal block, that is, the second halfframe of a radio frame in which a synchronization signal block islocated, time domain duration of a monitoring window is 1 slot, and atime domain offset between adjacent monitoring windows is equal to thetime domain duration of the monitoring window, that is, 1 slot. In thiscase, there is no overlap between the adjacent monitoring windows.Dashed blocks in FIG. 23 are pseudo synchronization signal blocks(pseudo SSBs), the transmission of the CORESET also avoids these pseudosynchronization signal blocks, and resources occupied by the CORESET inthe slot are the same as that in FIG. 22 .

The advantage of this configuration is that when the transmission periodof the synchronization signal blocks is 5 ms, synchronization signalblocks of the next period will also be transmitted in the slot in whichthe CORESET is located, and since the transmission of the CORESET avoidsthe resources for transmitting the synchronization signal blocks, evenif the transmission period of the synchronization signal blocks is 5 ms,there is no collision between the two. A terminal does not need to knowan actual synchronization signal block transmission period of thecurrent carrier.

FIG. 24 is a schematic diagram II that a CORESET is transmitted in aslot not containing a synchronization signal block according the presentembodiment. As shown in FIG. 24 , the CORESET is transmitted in a slotnot containing a synchronization signal block, that is, the second halfframe of a radio frame in which a synchronization signal block islocated, time domain duration of a monitoring window is 2 slots, and atime domain offset between adjacent monitoring windows is equal to ½ ofthe time domain duration of the monitoring window, that is, 1 slot. Thenthe adjacent monitoring windows partially overlap. In an embodiment, thesecond synchronization signal block in the slot 1 in which thesynchronization signal block is located is actually transmitted, thissynchronization signal block corresponds to the monitoring window 1,that is, the second and third slots of the second half frame, these twoslots include 4 CORESET transmission resources, and a base stationselects one of them to transmit the CORESET corresponding to thesynchronization signal block. Similarly, the first synchronizationsignal block in the slot 2 is actually transmitted, it corresponds tothe monitoring window 2, that is, the third and fourth slots, and thebase station selects one of the CORESET transmission resources in the 2slots to transmit a CORESET corresponding to this synchronization signalblock.

It should be noted that, CORESETs corresponding to differentsynchronization signal blocks cannot occupy the same CORESETtransmission resources; therefore, when CORESET transmission resourcesare selected in the corresponding monitoring windows for the subsequentsynchronization signal blocks, it is necessary to avoid CORESETtransmission resources having been occupied.

FIG. 25 is a schematic diagram that all synchronization signal blockscorrespond to a same CORESET monitoring window according the presentembodiment. As shown in FIG. 25 , all the synchronization signal blockscorrespond to a same CORESET monitoring window. In an embodiment, 4slots containing synchronization signal blocks include 8 synchronizationsignal block resources, in this case, only two of the synchronizationsignal blocks are transmitted, and the 8 synchronization signal blockscorrespond to the same CORESET monitoring window, and the monitoringwindow includes 8 CORESET transmission resources; and for a terminal, nomatter which synchronization signal block is received, it is necessaryto attempt to receive the corresponding CORESET on 8 CORESET monitoringopportunities in this monitoring window.

FIG. 26 is a schematic diagram that a plurality of synchronizationsignal blocks corresponds to one CORESET monitoring window according thepresent embodiment. As shown in FIG. 26 , the plurality ofsynchronization signal blocks correspond to one CORESET monitoringwindow. In an embodiment, 4 slots containing synchronization signalblocks include 8 synchronization signal block resources, in this case,the first 4 synchronization signal blocks are actually transmitted, 4synchronization signal blocks in the first 2 slots correspond to thefirst CORESET monitoring window (corresponding to the first 2 pseudosynchronization signal block slots in time domain), and 4synchronization signal blocks in the last two slots correspond to thesecond CORESET monitoring window (corresponding to the third and fourthpseudo synchronization signal block slots in time domain); and for aterminal, when one of the first 4 SSBs is received, it is necessary toattempt to receive the corresponding CORESET on 8 CORESET monitoringopportunities in the monitoring window 1, and when one of the last 4SSBs is received, it is necessary to attempt to receive thecorresponding CORESET on 8 CORESET monitoring opportunities in themonitoring window 2.

An indication bit may be introduced into a CORESET configurationinformation indication field of the PBCH to indicate a time domainoffset between adjacent CORESET monitoring windows of a current carrierto the terminal. For example, 2 bits are used for indication, ‘00’represents ‘the time domain offset between the adjacent monitoringwindows is 0’, ‘01’ represents ‘the time domain offset between theadjacent monitoring windows is a monitoring window length’, ‘10’represents ‘the time domain offset between the adjacent monitoringwindows is 1/X of the monitoring window length’, and ‘11’ represents‘state reservation’. X is an integer greater than 1, and a value thereofmay be specified in a protocol or indicated by a signaling.

In the foregoing indication manner, it is necessary to introduce 2-bitindication overhead, and in order to reduce this overhead, it is alsopossible to limit the type of the time domain offset between theadjacent monitoring windows according to different kinds of time domainduration of the monitoring window. For example, when the monitoringwindow length is 1 slot, it is specified that there are only twopossibilities for the time domain offset between the adjacent monitoringwindows: the time domain offset between the adjacent monitoring windowsis the monitoring window length (that is, the adjacent monitoringwindows overlap, and configured continuously), or the time domain offsetbetween the adjacent monitoring windows is 1/X of the time domainduration of the monitoring window (that is, the adjacent monitoringwindows partially overlap). In this case, only 1 bit is needed toindicate the offset value, for example, ‘0’ represents ‘the time domainoffset between the adjacent monitoring windows is a monitoring windowlength’, and ‘1’ represents ‘the time domain offset between the adjacentmonitoring windows is 1/X of the monitoring window length’. Similarly, Xis an integer greater than 1, and a value thereof may be specified in aprotocol or indicated by a signaling.

For a case that the monitoring window length is greater than 1 slot, itis specified that there are only two possibilities for the time domainoffset between the adjacent monitoring windows: the time domain offsetbetween the adjacent monitoring windows is 0 (that is, the adjacentmonitoring windows completely overlap), or the time domain offsetbetween the adjacent monitoring windows is 1/X of the monitoring windowlength (that is, the adjacent monitoring windows partially overlap). Inthis case, only 1 bit is needed to indicate the offset value, forexample, ‘0’ represents ‘the time domain offset between the adjacentmonitoring windows is 0’, and ‘1’ represents ‘the time domain offsetbetween the adjacent monitoring windows is 1/X of the monitoring windowlength’. Similarly, X is an integer greater than 1, and a value thereofmay be specified in a protocol or indicated by a signaling.

In the present application, the technical features in the respectiveimplementation manners may be used in combination in one implementationmanner without conflict. Each implementation manner is merely an optimalimplementation manner of the present application.

This embodiment provides a transmission method of common controlinformation block configuration information, and with this solution,time and frequency domain resource positions of a control resource setcan be effectively indicated without affecting combined reception ofPBCHs (that is, it is ensured that the PBCH content in each SS block isthe same). In addition, by configuring time domain duration of a controlresource set monitoring window and a time domain offset betweenmonitoring windows corresponding to adjacent SS blocks, transmissionresources of a common control block are more flexible, and the impact ofburst traffic transmission on the common control block transmission iswell avoided.

Embodiment 4

An embodiment of the present application further provides a storagemedium, and the storage medium includes a stored program, where themethod according to any one of the foregoing is executed when theforegoing program is run.

In the present embodiment, the foregoing storage medium may beconfigured to store program codes for executing the following step S1and step S2:

In the step S1, configuration information of a control resource set iscarried on a physical broadcast channel; where the configurationinformation is used to indicate to a terminal at least one of thefollowing of the control resource set: time domain position informationand frequency domain position information.

In the step S2, the control resource set is transmitted to the terminalaccording to the configuration information.

In an embodiment, in the present embodiment, the foregoing storagemedium may include, but is not limited to: any medium that can storeprogram codes, such as a USB flash drive, a read-only memory (Read-OnlyMemory, ROM), a random access memory (Random Access Memory, RAM), aremovable hard disk, a magnetic disk, or an optical disk.

An embodiment of the present application further provides a processor,and the processor is configured to run a program, where the stepaccording to any one of the foregoing methods is executed when theprogram is run.

In the present embodiment, the foregoing program is used to execute thefollowing step S1 and step S2:

In the step S1, configuration information of a control resource set iscarried on a physical broadcast channel; where the configurationinformation is used to indicate to a terminal at least one of thefollowing of the control resource set: time domain position informationand frequency domain position information.

In the step S2, the control resource set is transmitted to the terminalaccording to the configuration information.

In an embodiment, the specific example in the present embodiment mayrefer to the example described in the foregoing embodiment and optionalimplementation manner, and it will not be repeated redundantly herein.

Obviously, those skilled in the art should understand that the foregoingeach module or each step of the present application may be implementedby universal computing devices, and they may be centralized on a singlecomputing device or distributed over a network consisting of a pluralityof computing devices; in an embodiment, they may be implemented byexecutable program codes of a computing device, and thus they can bestored in a storage device for execution by the computing device; and insome cases, the illustrated or described steps may be executed in anorder different from the one herein, or they are respectively fabricatedinto individual integrated circuit modules, or a plurality of modules orsteps thereof are implemented by being fabricated into a singleintegrated circuit module. Thus, the present application is not limitedto any specific combination of hardware and software.

What is claimed is:
 1. A method, comprising: transmitting, to aterminal, configuration information of a common control resource set ona physical broadcast channel, wherein the common control resource set isfor remaining minimum system information (RMSI), the configurationinformation indicating time domain position information of the commoncontrol resource set, the time domain position information of the commoncontrol resource set including: (1) information of a first slot in whichthe common control resource set is located, (2) a starting symbol indexof at least one symbol occupied by the common control resource set inthe first slot, and (3) a number of the at least one symbol occupied bythe common control resource set in the first slot, the at least onesymbol occupied by the common control resource set in the first slotincluding at least one of the third symbol, the fifth symbol, theseventh symbol, or the ninth symbol of the first slot; and transmitting,to the terminal, the common control resource set according to theconfiguration information.
 2. The method of claim 1, wherein the firstslot in which the common control resource set is located contains asynchronization signal block (SSB).
 3. The method of claim 2, whereinthe common control resource set is transmitted in a second slot notcontaining the SSB, and a same resource mapping rule is applied for thecommon control resource set in both the first slot containing the SSBand the second slot not containing the SSB.
 4. The method of claim 2,wherein the starting symbol index of the at least one symbol occupied bythe common control resource set in the first slot and a starting symbolindex of symbols occupied by the SSB in the first slot are the same. 5.A method, comprising: receiving, by a terminal, configurationinformation of a common control resource set on a physical broadcastchannel, wherein the common control resource set is for remainingminimum system information (RMSI), the configuration informationindicating time domain position information of the common controlresource set, the time domain position information of the common controlresource set including: (1) information of a first slot in which thecommon control resource set is located, (2) a starting symbol index ofat least one symbol occupied by the common control resource set in thefirst slot, and (3) a number of the at least one symbol occupied by thecommon control resource set in the first slot, the at least one symboloccupied by the common control resource set in the first slot includingat least one of the third symbol, the fifth symbol, the seventh symbol,or the ninth symbol of the first slot; and receiving, by the terminal,the common control resource set according to the configurationinformation.
 6. The method of claim 5, wherein the first slot in whichthe common control resource set is located contains a synchronizationsignal block (SSB).
 7. The method of claim 6, wherein the common controlresource set is transmitted in a second slot not containing the SSB, anda same resource mapping rule is applied for the common control resourceset in both the first slot containing the SSB and the second slot notcontaining the SSB.
 8. The method of claim 6, wherein the startingsymbol index of the at least one symbol occupied by the common controlresource set in the first slot and a starting symbol index of symbolsoccupied by the SSB in the first slot are the same.
 9. A base stationcomprising a processor configured to: transmit, to a terminal,configuration information of a common control resource set on a physicalbroadcast channel, wherein the common control resource set is forremaining minimum system information (RMSI), the configurationinformation indicating time domain position information of the commoncontrol resource set, the time domain position information of the commoncontrol resource set including: (1) information of a first slot in whichthe common control resource set is located, (2) a starting symbol indexof at least one symbol occupied by the common control resource set inthe first slot, and (3) a number of the at least one symbol occupied bythe common control resource set in the first slot, the at least onesymbol occupied by the common control resource set in the first slotincluding at least one of the third symbol, the fifth symbol, theseventh symbol, or the ninth symbol of the first slot; and transmit, tothe terminal, the common control resource set according to theconfiguration information.
 10. The base station of claim 9, wherein thefirst slot in which the common control resource set is located containsa synchronization signal block (SSB).
 11. The base station of claim 10,wherein the common control resource set is transmitted in a second slotnot containing the SSB, and a same resource mapping rule is applied forthe common control resource set in both the first slot containing theSSB and the second slot not containing the SSB.
 12. The base station ofclaim 10, wherein the starting symbol index of the at least one symboloccupied by the common control resource set in the first slot and astarting symbol index of symbols occupied by the SSB in the first slotare the same.
 13. A terminal comprising a processor configured to:receive configuration information of a common control resource set on aphysical broadcast channel, wherein the common control resource set isfor remaining minimum system information (RMSI), the configurationinformation indicating time domain position information of the commoncontrol resource set, the time domain position information of the commoncontrol resource set including: (1) information of a first slot in whichthe common control resource set is located, (2) a starting symbol indexof at least one symbol occupied by the common control resource set inthe first slot, and (3) a number of the at least one symbol occupied bythe common control resource set in the first slot, the at least onesymbol occupied by the common control resource set in the first slotincluding at least one of the third symbol, the fifth symbol, theseventh symbol, or the ninth symbol of the first slot; and receive thecommon control resource set according to the configuration information.14. The terminal of claim 13, wherein the first slot in which the commoncontrol resource set is located contains a synchronization signal block(SSB).
 15. The terminal of claim 14, wherein the common control resourceset is transmitted in a second slot not containing the SSB, and a sameresource mapping rule is applied for the common control resource set inboth the first slot containing the SSB and the second slot notcontaining the SSB.
 16. The terminal of claim 14, wherein the startingsymbol index of the at least one symbol occupied by the common controlresource set in the first slot and a starting symbol index of symbolsoccupied by the SSB in the first slot are the same.